Scanning system and apparatus



7 Sheets-Sheet 1 INVENTOR LOUIS M. POTT$,DECEASED MARTHA W; C. POTTS,EXECUTRIX BY ATTORNEY Feb. 19, 1952 L. M. POTTS SCANNING SYSTEM AND APPARATUS Original Filed June 4, 1947 L. M. POTTS SCANNING SYSTEM AND APPARATUS '7 Sheets-Sheet 2 Feb. 19, 1952 Original Filed June 4, 1947 INVENTOR LOUIS M. POTTS,DEGEASED MARTHA W. C. POTTS,EXECUTRIX ATTORNEY Feb. 19, 1952 o s 2,586,711

SCANNING SYSTLEM AND APPARATUS Original Filed June 4, 1947 7 Sheets-Sheet .3

FIG. 4 I32 I INVENTOR v LOUIS M. POTTS, DECEASED MARTHA w. c. POTTS, ExEcuTmx BY Wag TORNEY Feb. 19, 1952.

L. M. PoTTs SCANNING SYSTEM AND APPARATUS 7 Shet-s-Sheet 4 0riginal -Filed Jiine i, 1947 FIG. 6

FIG.8

FIG.

FIG. IO

Em SE m T H T W M A o Mm A l .W

A Sm Feb. 19, 1952 L. M. POTTS SCANNING SYSTEM AND APPARATUS Original Filed June 4, 1947 7 Sheets-Sheet 5 FIG. 9

FIG. I3

INVENTOR m m 5 E M X a T m "P O C. .w M T IR WA LM FIG. ll

ATTORNEY Feb. 19, 1952 L. M. POTTS SCANNING SYSTEM AND APPARATUS Original Filed June 4, 1947 7 Sheets-Sheet 6 INVENTOR LOUIS M. POTTS, DECEASED MARTHA W. C. POTTS,EXECUTRIX ATTORNEY L. M. POTTS SCANNING SYSTEM AND APPARATUS Original Filed June 4, 1947 7 Sheets-Sheet 7 INVENTOR LOUIS M. POTTS,DECEASED WWIIMARTHA w. c. POTTS,EXECUTRIX Patented Feb. 19, 1952 SCANNING SYSTEM AND APPARATUS Louis M. Potts, deceased, late of Evanston, 111., by Martha W. C. Potts, executrix, Evanston, Ill., assignor to Teletype Corporation, Chicago, 111., a corporation of Delaware Original application June 4, 1947, Serial No.

Divided and this application November 5, 1948, Serial No. 58,505

20 Claims. 1

This invention relates to scanning systems and apparatus, and particularly'to systems wherein printin telegraph apparatus is used for recording code marks on a page form and the form is subsequently scanned by a photoelectric transmitter which transmits signals accordingly.

This application is a division of copending application Serial No. 752,512, filed June 4, 1947, now U. S. Patent No. 2,540,287 of February 6, 1951.

An object of the invention is to provide apparatus for scanning from a page form both printed characters and corresponding code marks, and in which the code marks so provided are scanned by a photoelectric transmitter for transmission purposes.

Another object of the invention is to provide photoelectric transmitting apparatus which scans a page form having code marks thereon, line by line, and transmits signals according to the code marks so scanned.

A further object of the invention is to provide a photoelectric transmitter which converts the signal representations of one equal length code into the signal representations of another equal length code with automatically inserted shift signals.

Still another object of the invention is to provide a photoelectric transmitter which automatically transmits a carriage return signal.

A feature of the invention is the use of a traveling projector in a photoelectric transmitter which after completing the scanning of a line of code marks on a page form is automatically returned to its beginning of line position preparatory to scanning the next line of code marks. When the projector reaches the beginning of line position, the page form is advanced to place the next line of code marks in scanning position.

Another feature of the invention is the use of a pivoted projector for scanning control form indicia wherein the focal length of the projector is automatically adjusted according to the area of the form being scanned.

Other objects, features, and advantages of the invention, although not specifically recited above, will become apparent as the invention is later described in detail.

The photoelectric transmitter includes a pivotally mounted projector whose free end moves across a line of code marks reproduced on a page form, stopping at each code combination to transmit the signal and then resuming its travel to the next code combination. When the end of the line is reached, the projector is automatically returned to the beginning of line position as a new line of code marks is fed into scanning position.

Sequential transmission of the code impulses and the start-stop impulses by operation of a photoamplifier tube, is obtained by means of a scanning disc. The scanning disc consists of an opaque circular plate having arcuate transparent areas arranged at difierent radial distances and in different angular positions about the center point. These arcuate areas represent the six elements of the code combination and the stop impulse. A start impulse is a no current impulse and therefore no transparent area is provided in this case, the opacity of the circular plate being relied upon to send the start impulse. The feed marks are scanned by a continuous transparent ring of the scanning disc when a shutter is in one of its two positions, and at this time the code marks are blocked. In its other position, the shutter permits scanning of the code marks and blocks scanning of the feed marks. A suitable circuit arrangement is provided for use with this photoelectric transmitter for the transmission of a siX unit code signal.

The invention also provides a modified form of transmitter which converts the six unit code into a five unit code with automatically inserted shift and unshift signals and carriage returnsignals. However, it should be pointed out that the photoelectric transmitting apparatus disclosed herein, is designed to be used either in the six unit code system, or in the five unit code system. A different circuit arrangement is used in conjunction with the photoelectric transmitter designed to transmit five unit code signals.

In each of the photoelectric transmitters, provision is made should abnormal spacing occur between code mark combinations. When this condition is encountered, the stop impulse between characters is prolonged and thus no detrimental results will occur at the receiving end of the line since in start-stop telegraph practice the receiving cam sleeve would be held in its stop position until a start impulse is received. The transmission of the code combination of the abnormally spaced characters is in this way delayed but is transmitted intact without impairing transmission.

A more ready comprehension of the invention may be had by reference to the following detailed description when read in conjunction with the drawings wherein:

Fig. 1 is a plan view of the photoelectric transmitting apparatus with parts broken away and parts omitted to avoid confusion in the drawings;

Fig. 2 is a detail of a braking mechanism which forms part of the photoelectric transmitter;

Fig. 3 is a section view of the photoelectric transmitter taken on the line 33 of Fig. 1;

Fig. 4 is a section view of the transmitting apparatus taken on the line 4-4 of Fig. 3;

Fig. 5 is a partial plan view of the transmitting apparatus devoted particularly to the feeding of the page form;

Fig. 6 is a detailed view of the scanning disc used in connection with transmission of a six unit code; I

Fig. 7 is a detailed view of the scanning disc used in connection with transmission of a five unit code;

Fig. 8 is a rear view of a page form illustrating printed code mark combinations and feed marks;

Fig. 9 is a view identical with that shown in Fig. 8 and duplicated for convenience in reading the specification;

Fig. 10 is an enlarged detail View of the end of the projector used for six unit code transmission particularly for the purpose of showing the code mark and feed mark openings;

Fig. 11 is an enlarged detail view of the end of the projector used for five unit code transmission particularly for the purpose of showing the code mark and feed mark openings;

Fig. 12 is a detail of the shutter used for six unit code transmission;

Fig. 13 is a detail of the shutter used for five unit code transmission;

Fig. 14 is a circuit arrangement used for six unit code transmission; and

Fig. 15 is a circuit arrangement used for five unit code transmission.

The prepared coded page utilized in the present invention may be prepared by the apparatus disclosed in copending application Serial No. 152,512, filed on June 4, 1947, in the name of L. M. Potts, or by any other known and suitable-means.

Referring now particularly to Figs. 1 to 13, the photoelectric transmitting apparatus provided in the present invention will be described. A pictorial representation of a portion of the rear of a page form 2| to be scanned by the photoelectric transmitter is shown in Fig. 8 with the code marks appearing thereon corresponding to related characters appearing on the front of the page form. Numeral 22 represents the base of the apparatus upon which is mounted a motor 23 for providing rotary movement of main shaft 24 by means of gears 28 and 21. Shaft 24 is journaled on the upright supports 28 and 29 and has fixedly attached thereto a scanning disc 3|, shown in detail in Fig. 6.

Extending across the top of the apparatus is 'a cross support 32 into which is threaded a downwardly extending pivot stud 33. Supported about pivot stud 33 is a ball bearing 34 encased in a member 36 which is rigidly secured to the oscillating projector generally indicated as numeral 31. Projector 31 includes two separate lens carrying elements 38 and 39, each movable in the cylindrical or tube portion 4| of the projector. Upon oscillation of the projector, as will later be described, sliding movement of lens element 38 is produced by reason of the engagement of a pin 42 carried thereby in a slot 43 of a cross piece 44. Sliding movement of lens element 39 is similarly produced by engagement of pin 45 in slot 41 of crosspiece 48. It is to be understood that the tube portion 4| of the projector, atthe places where engaged by pins 42, 48, will be provided with suitable clearances to permit the sliding movement of elements 38 and 39. Because of the construction just described above, the focal length of the projector 31 may be varied according to the area of the page form 2| being scanned as will later become more apparent.

One end of the projector 31 is covered by a plate 49 having openings '5|| to 5|6, 5|-F (Fig. 10) and an opening 5 |S which are adjacent to the scanning disc 3|. The openings just mentioned are made narrower than the image received therethrough so that when a code mark or a feed mark is scanned it will completely cover the opening to which it is related. This further allows a slight misalignment between the projector 31 and the code marks of page form 2|.

At the top of the apparatus is a guideway 52 composed of a guiding plate 53 and the top plate 54 of the apparatus. Plate 53 is of transparent material to allow viewing of the printed characters on the page form. Plate 54 is slotted at 58 so as to expose one line of code marks to a suitably mounted mirror 51. Light for the optical system is provided by a fluorescent lamp 58 extending across the apparatus at the top of the mirror 51. Mounted between plate 49 of projector 31 and scanning disc 3| is a thin opaque shutter 59 shown in detail in Fig. 12 which is mounted on an armature 6| of a magnet 62. Shutter 59 is movable to two different positions as will later appear. In one position it will permit the passage of light for scanning purposes through feed hole opening B3-F formed thereon, from opening 5|-F of plate '49 and at this time block all of the openings 5|--| to'5|6 and 5|S. In the other position, projection 64 of shutter 59 is interposed in front of feed hole opening 5l-S and all the code mark openings are unblocked for scanning purposes.

With reference now to Fig. 6, the scanning disc 3| will be described in more detail. Its purpose is to selectively control the passage of light to a photoamplifier tube 66 suitably mounted in'the apparatus. Scanning disc 3| consists of an opaque circular plate having arcuate transparent areas '61| to 616, progressively arranged about the center point at different radial positions which are in line with corresponding openings in plate 49 of projector 31. In addition, an arcuate transparent area 61-8 is provided for the start impulse while a continuous transparent ring 5'1-F is provided for scanning of the feed mark. The start impulse is provided by painting a line the same color as the page form across the underneath part of plate 54 adjacent'the slot 56. No arcuate transparent area is providedfor the Stop impulse since this corresponds to a marking 1m pulse and at this time an opaque portion of disc 3| which lies between areas 61-6 and 61-S will be presented in scanning position with respect to photoamplifier tube 66.

The mechanism for moving the free end of the projector 31 'back and forth across the apparatus for scanning purposes will now be explained. Fast to main shaft 24 is a gear 58 which is in mesh with a gear 69 carried by a-second shaft 1|. The latter shaft has fixed thereto a gear 12 "in mesh with a gear 13 rotatably mounted about shaft 24 on sleeve 14. Friction washer 15, 11 operable by arms 18 and 18 of armature8l of magnet 82 act as a clutch to enable the rotation of a gear 82 with the gear 13. The previously described gearing provides a speed reduction for the gear 83. Gear 83 is in mesh with a rack 84 which is suitably connected to projector 31 by means of a pin 86. Thus, when clutch magnet 82 is periodically energized, gear 83 will drive the rack 84 to the left as viewed in Fig. 4, causing "the projector 31 to move also periodically to the left to scan a line of code marks as will hereafter appear. Rack 84 is provided with rollers 81 which ride in the slotted guideway 88. For returning the projector 31 to the beginning of line position, a gear 89 is provided which is also in mesh with the rack 84 and is carried rotatably about the shaft H on a sleeve 9I. When gear 83 drives rack 84,gear 89 moves idly about the shaft 1| in a counter-clockwise direction. Return movement of gear 89 is under the control of a single revolution clutch indicated generally at 92 the opera tion of which is governed by a clutch magnet 93 in a manner well known in the art. Stop arm 94 is operable under the control of armature 96 of clutch magnet 93 as will be later described in detail. When the clutch 92 is released sleeve 96 rotates until a lug 91 carried thereby engages a lug 98 carried by the gear 89. When this occurs, gear 89 will rotate in a clockwise direction and drive rack 84 back to its beginning of line position. The length of the previous line scanned determines at what point lug 91 will engage lug brake I8I, urged in a counterclockwise direction (Fig. 1) by means of a spring I62, and carrying brake material I63 which presses against the side of rack 84 through the opening in guideway 88. Arm 19 of armature 8I has an extension I64 which operates against one end of a lever I86 pivoted at I81, causing a projection I88 carried at its other end to operate against brake II and free it from rack 84 when clutch magnet 82 is energized. At this time gear 89 may drive rack 84 to the left as shown in Fig. 4. When the projector unit is being returned to the beginning of line position, clutch magnet 93 will operate and sleeve 96 will be released for rotation as explained. Sleeve 98 carries a cam i09 which operates a follower slide lever III, which by pushing against the shorter arm of brake IUI, also frees the brake so that gear 89 may be permitted to drive rack 84 to the beginning of the line position. Just before this position is reached cam I09 operates lever III and permits brake IIII to move to its braking position preventing the optical unit from being jarred or rebounding. It is :z

apparent then, as rack 84 is operated, projector 31 will be pivoted and lens sections 38, 39 will slide in the tube 4| to automatically adjust the focal length of the projector according to the area of the page form being scanned.

A description of the page form feeding mechanism will now be given. On shaft 24 is rigidly attached a gear I I2 which is in mesh with a gear II3 carried on a shaft II4 journaled on supports H6 and H1. At one end, shaft H4 has secured thereto a small gear II8 which is in mesh with a large gear II9 mounted on a shaft I2I. Shaft I2I is mounted in bearings I22 and I23 and supports the paper feed roll I24 which is con stantly rotated through the just described gearing arrangement. Mounted for vertical sliding movement at either side of the apparatus on brackets I26 and I21 are members I28 and I29 which support at their upper ends a pressure roller shaft I 3| extending therebetween. Shaft I3I supports the pressure roller I32. The lower ends of members I28 and I29 are connected by a cross rod I33 the middle portion of which has attachedthereto an armature I34 which is under the control of a magnet I36. Compression springs I31 normally urge members I28 and I29 to an upward position so that pressure roller I32 is free of constantly rotating feed roll I24 and no feeding of the page form takes place. At this time a brake member I38 also supported from members 128 and I29 and having brake material I39 holds the paper from movement against the upper guideway 53 as is shown clearly in Fig. 3. However, when armature I34 is attracted upon energization of magnet I36 members I28 and I29 are pulled down against the tension of springs I31, freeing brake member I38 from the page form and enabling pressure rollers I32 to force the page form 2I against feed roll I24. At this time the page form is fed forward as will more readily hereinafter appear in connection with the description of the circuit arrangements.

Before a description of the first circuit arrangement is undertaken, attention is called to switch cams I4I, I42, and I43 mounted on the constantly rotating shaft 24 of the transmitting apparatus and to contact bank I44 at the right side of Fig. 4. It is to be understood as has been pointed out before, that the apparatus is adapted to be used either for transmission of a six unit code or with some modifications for an arrangement wherein six unit code signals are converted into five unit code signals with automatically inserted shift signals.

The circuit arrangement for transmitting six unit code signals will now be described with particular reference to Fig. 14. Numeral I46 represents an alternating current power source which furnishes power for the motor 23 and for the primary I41 of a transformer I48. Power for the illumination of the previously identified fluorescent lamp 58 is provided from secondary I49 of transformer I48 by means of rectifier filter I5I. The other secondary I52, by means of rectifiers I53, inductances I54, and condensers I56, furnish current for operation of photoamplifier tube 66 and the primary of a transformer I51. The secondary I52 of transformer I48 is tapped at its midpoint and grounded. The elements of photoamplifier tube 66 are connected to taps of a resistance I58 to provide varying potentials with the most positive potential applied to the element adjacent collector plate I591 As the code marks are scanned and light is impinged on the photoamplifier tube 66, if unprinted areas are scanned, there is a substantially uniform current in the primary of transformer I51. If all areas scanned in succession have printed code marks, again a substantially uniform current flows in the primary of transformer I51 but in this case it is of a lower value. Under either of the above steady state conditions just outlined above, no current will flow in the secondary of transformer I51. The secondary of transformer I51 is connected to the grid of tube I6I, the plate of which is in series with the primary of a transformer I62. The secondary of transformer I62 is grounded at its midpoint and is associated with rectifiers I68, I64, which respectively may pass positive impulses to the grids of tubes I66, I61. The plate circuit of tube I66 is connected to positive potential through resistance I68 and onewinding of commutating transformer I69, while the plate circuit of tube I61 is connected to positive potential through resistance HI and the other winding of transformer I69. Tubes I66, I61, are gas discharge tubes and are designed to remain in the condition last assumed.

If a printed area is being scanned and during the nextimpulse interval an unprinted area is scanned, the value of the current flowing in the primary of transformer I51 suddenly changes inducing a voltage in the secondary, of transformer I51, which is then amplified by tube IEI, the amplified output of which is applied through transformer I62 to rectifiersl93 and IE4 in series with grid load resistor I12. Grids of tubes I86 and I61 are normally biased negatively by means of positive battery applied through tapped resistor I13 to the cathodes, precluding tubes I66 and I81 from firing prior to a-signal impulse being received from the photoelectric source.

Positive voltage impulses appearing across the secondary of transformer I52 arepassed by rectifiers IE3 and I64, raising the grid potential of tubes I69 or I91 to a value approximately equal to the existing positive cathode ground potential, causing the respective tube to ionize. A subsequent positive impulse on a grid of the opposite tube causes it to ionize or fire and extinguish the previously ionized tube.

It will be assumed that when passing from printed areas to unprinted areas that rectifier I64 passes current and then tube I61 will be fired. When this occurs the current set up in its associated winding sets up a current in the winding associated with tube I66 which extinguishes the latter tube. On the other hand, when passing from unprinted to printed areas, rectifier I63 passes positive potential and allows tube I66 to fire and the action of transformer IE9 is to now extinguish tube I61. When printed areas are scanned, transmitter relay I14 energizes and when unprinted areas are scanned, relay I14 is de-energized. Thus, relay I14 will remain in its last operated position in accordance with the firing of gas discharge tubes I69, I61, in response to the scanning of successively opposite conditions of the page form.

As previously mentioned, cams I4I, I42, and I43 are mounted on the main shaft 24 which also carries the scanning disc 3|. The relationship of these cams to the scanning disc 3I is clearly shown in Fig. 6 wherein it is observable that cam I4! has a high portion which extends the whole length of the stop impulse, the high portion of cam I42 is only half as long as cam MI and cam I43 has a small high portion which operates near the end of the stop impulse.

It will now be assumed that the transmitter is operating and relay I14 is accordingly transmitting signals over a line I16 to a distant station I11. A further assumption will be made that shaft 24 has now reached the position shown in Fig. 14. A circuit may now be traced as follows: From battery, through the winding of shutter magnet 62, over conductor I18 and through contact tongue I19 (now closed) of cam I4I to ground. With shutter magnet 62 energized, shu ter 59 moves to a positionto block scanning of the code marks just transmitted, unblocking the feed mark related to said last transmitted code marks. At this time, a circuit is also traceable as follows: From battery, through the winding of clutch magnet 82, through contact pair I8I (now closed), over lead I82, through tongue I83 (now on its back contact) of double wound relay I84, over leads I86, I81, through closed contact tongue I98 operable from cam I42, and through the contact tongue I89 of a polar relay I9I to ground. Contact tongue I89 is new on its left contact as will later be described. Magnet 82 is thus energized at this time and the projector 31 is accordingly advanced as was previously described in connection with the mechanical part 'of the invention and moves towards the next feed mark. After contact tongue I88 of cam I42 opens, the projector will have moved'oif the feedmark accompanying .the code marks just scanned and will be scanning an unprinted area between feed marks, and relay I 1'4v will be de-energized and relay I92 will be. energized over an obvious circuit as contact tongue I93 of relay I14 falls to its back contact. The circuit for clutch magnet 82 now extends as follows: From ground, through contacttongue I 94 of relay 1 92, over lead I 96, through contact tongue I91 (still closed) of cam MI and over lead I98 to the .circuitpreviously described extendingfrom lead I86 to clutch magnet 82.

As clutch magnet 82 remains energized, projector 31 continues to advance as pointed out above until the next feed mark is encountered, it being remembered that shutter59 is at this time in its feed mark scanning position. When such a feed mark is encountered transmitter relay I14 will operate and contact tongue I93 will be drawn up to break the circuit to'relay I92. .Opening of contact tongue I94 ofrelay I92 breaks the previously described circuit for clutch magnet 82 extending through tongue I94 and the projector 31 comes to rest.

When contact tongue I99 isclosed'by cam I43 the projector should have reached the next feed mark, if the spacing between feed marks is normal. 'Underthis assumed condition transmitting relay I14 will energize and'relay I92 willd-ehergize moving its tongue 29I to its back contact as previously described and completing a circuit as follows: From ground, over lead 202, through the left winding'of polar relay I9l, over lead'203, and through contact tongue I99, and contact tongue 294 of cam 209 carried by carriage return sleeve to battery. Under'this condition contact tongue I89 will remain in the same-position against the left-hand contact. What happens when abnormal spacing occurs will be explained later. i r

When contact I19 is opened by cam I4I to open the circuit for shutter magnet 62, the shutter 59 moves to its code mark scanning position to allow scanning disc 3I to scan the code marks of the signal code combination accompanying the feed mark which caused the advancement of projector 31 to be halted. However, the painted lin'e previously identified as being painted beneath plate 54, adjacent slot 56 of the apparatus is scanned to first send the start or no current. impulse, causing contact tongue I93 of relay I14 to move to its spacing position. During the stop impulse period, line I16 is maintained closed by a shunting circuit extending over lead 201, through contact 208 of cam I4I and over lead 209 to battery lead 2II. Thus, regardless of the operation of. relay I14 during, the stop impulse period, line I16 is left closed. After the start impulsev is transmitted the arcuate transparent areas 61-] to 61--9 of disc 3| sequentially sweep past related openings 5II to 5I-9 of plate 49 ofthe' projector to sequentially scan the printed code marks and operate photoamplifier tube 66 andtransmittin relay I14 accordingly. When the stop impulse position'of scanningdisc 3| "is reached the cycle of operation described above is repeated. It will be understood that although printed characters are not printed in response to the letter space signal by the page printers described earlier in the specification, that corresponding codemarks are printed with theusual .Fig. 14 is exactly the same. However, when contact I99 is closed, relay I92 will be energized since the projector 31 has not yet reached the next feed mark and is scanning a white area of the page form. When this occurs ground extending from contact tongue 20I of relay I92 completes a circuit over lead 2I2 through the right-hand winding of polar relay I9I and over lead 293 through contact I99 of cam I43 and 1,6

through contact 204 of cam 208 to battery. As a result, contact tongue I89 moves against its right contact and remains in this position for an entire cycle or until contact I99 is again closed by the highportion of cam I43 after the go next feed mark is reached as will be explained below. An obvious circuit is now made extending over lead 2 I3 for relay 2I4. When relay 2 I4 is energized, it pulls up its tongue 2 I6 and places a steady marking current on line I16 over the g g-p lead 2I1 for a complete cycle of operations and no code signal will be transmitted during this interval. The scanning disc 3| will make its usual rotation but at this time contact tongue 2I8 of relay 2I4 will be closed to maintain shut-$13 ter magnet 62 operated over lead I18. Shutter 59 thus remains in its feed mark scanning position and does not permit scanning of the code marks.

During this time, the projector continues to advance towards the next feed mark since clutch magnet 82 is now held energized over a circuit extending from grOund at contact tongue I94'of relay I92 (now energized), over lead I 96, through contact tongue 2I9 (now closed) of relay 2I4,

over lead I81 to the previously described circuit extending over lead I86 to clutch m'agnet82. However, when the next printed feed mark is scanned, relay I14 will be energized and relay I92 will be de-energized, opening contact tongue I94 and breaking the just described circuit for clutch magnet 82 bringing the projector to rest.

vWhile shaft 24 continues to rotate after cam I43 has closed contact tongue I99, as previously described, projector 31 proceeds toward the abnormally spaced feed mark. Usually, it will find this feed mark before shaft 24 has completed another revolution and will cause clutch magnet 82 to de-energize and stop projector 31 as described above. When cam I42 closes contact I38 the original operating circuit for clutch magnet 82 cannot be completed since contact tongue I89 of polar relay I9I is still on its right-hand contact and the projector will be held at rest to scan the code combination delayed in the previous cycle. Now when contact I99 is closed immediately after, tongue I of relay I92 is on its back contact since the next feed mark is now being scanned and relay I14 is energizedand relay I92 is de-energized. Therefore, a circuit will be come pleted to the left-hand winding of polar relay I9I, causing the de-energization of relay 2I4 as contact tongue I39 moves to the left. Tongue 2 I8 of the latter relay falls away opening the circut of shutter magnet permitting the code marks to be scanned and contact tongue 216 of the same relay falls away taking the battery off lead 2I1, permitting relay I14 to send the start impulse over line I16. The signal delayed by the abnormal spacing is now transmitted and nor mal operation continues until abnormal spacing is again encountered. On the following cycle, clutch magnet 82 may again be energized since contact tongue I99 of polar relay I9I is again on its left contact and the projector 31 may move to the next feed mark as described to scan its accompanying code marks.

Operation of, the end of line mechanism for returning the projector 31 to its beginning of lineposition will now be explained. As the projector 31 continuesto advance after scanning the last set of code marks of the line, it will scan a relatively long unprinted area. It should be mentioned at this time that when relay 214 is operated when an abnormal white feed mark is scanned, it will send a pulse to a slow-to-operate relay 22 I. If the unprinted area produces a pulse long enough to operate relay I92 for more than one cycle, a tongue I93 of transmitting relay I14 moves against its back contact, relay 2 I4 will stay operated for at least two complete cycles. At this time relay 2I4 will pull up its tongue 2I6 and maintain a marking condition on line I16 as before. Furthermore, it should be mentioned that closure of tongue 2I8 by the same relay maintains a circuit for shutter magnet 62. Relay 2I4 will now stay energized long enough to enable its contact tongue 222 to operate slow-t0- operate relay 22 I.

When slow-to-operate relay 22I is operated, a circuit is made through its contact tongue 223 and over lead 224 for the clutch magnet 93, which it will be recalled controls the operation of the carriage return mechanism. Armature 229 of clutch magnet 93 now pivots counterclockwise as viewed in Fig. 4 and carries with it latch 221 which is pivoted at 228 on armature 22B and urged clockwise by a spring 229. Nose 23I of latch 221 now engages the lower end of clutch stop arm 94 causing it to be pivoted about the points 232 in a clockwise direction against the influence of spring 233. This frees the clutch 92 for operation and gear 89 functions to drive the projector to its beginning of line position. Near the end of the movement of armature 22 9, latch 221 engages a fixed pin 234 which results in pivoting latch 22'! counterclockwise freeing its nose 23I from the lower end of stop arm 94 and allow ing the stop arm to return to its stopping position and insuring that the clutch 92 will make only a single revolution. When clutch magnet 93 is deenergized armature 229 is operated clockwise about its pivot 23 5 by operation of a relatively strong spring 231. At this time nose 23I will 'snap past the lower end of stop arm 94 and move 'to its original position. It is apparent then, that even though magnet 93 may remain energized, clutch 92 will permit only a single revolution of sleeve 96. v I

When the projector 31 reaches the beginning of line position roller 91 at the rightlFig. 4) which moves in slotted guideway 89 will operate contact bank I44 and tongue 238 associated therewith which has been in a position to enable condenser 239 to become charged. Condenser 239 now discharges through the left-hand winding of double wound relay I84, over lead 24I when contact 242 is closedby cam I 42. Relay 22I is so adjusted that it operates a predetermined time after relay 2I4 and thusthe projector will start its return movement at a fixed time. Further, the gearing will be such that projector 31 reaches the beginning of the line after shaft 24 has made a predetermined number of revolutions. As a result, contact tongue 238. is operated with shaft 24 in a predetermined angular position. Preferably, the timing is such that contact tongue 238 will move against left-hand contact just prior'to the time that contact tongue I88 is closed by the high part of cam I42. When contact tongue 242 of cam I42 closes, the circuit for double wound relay I84 is made as already described. Relay I84 will now lock up through its contact tongue 243, over lead 244, and through contact tongue 246 of cam I42. When the beginning of the line was reached the margin feed mark appearing in the margin at the right of that line is scanned at this time and relay I92 will be de-energized. However, when the projector scans a white or blank area as will appear hereafter, contact tongue 20I of relay I92 will be drawn up and complete a locking circuit over lead 244 for relay I84. While the projector 31 is returning to its beginning of line position, carriage return sleeve 96*by means of Ushaped lever 241 which is provided with pins 248 resting in collar 249, opens contact pair I8I to prevent operation of clutch magnet 82 during this period.

When relay I84 is operated, a circuit is made through line feed magnet I36, over lead 25I, through contact tongue I83 of relay I84 (now on its front contact), over leads I86 and I81, through closed contact I88 of cam I42, and over lead 252 to contact tongue 253 now drawn up by slow-to-operate relay 22I. When the page form is fed, the projector will scan a white area existing between the outermost or margin feed mark of the line of code marks just scanned and the outermost or margin feed mark of the new line of code marks. It is at this time the. locking-circuit is maintained for relay I84 from contact tongue 20I of relay I92 as mentioned above. Contact tongue 2I8 of relay 2I4 is, therefore, maintaining shutter magnet 62 energized and contact tongue 2I6 of the same relay ismaintaining condition of line I16. It should be noted that when the projector is returning to its beginning of line position, carriage return sleeve 98 rotates to open contact 204 by means of cam 205 so that regardless of the operation of relay I 14, the windings of polar relay I9I cannot be pulsed and tongue I89 will remain on its right contact. Just before the carriage reaches its beginning of line position, contact 204 will close but meanwhile the high portion of cam I43 will have already operated contact I99 and operation of tongue I99 during the carriage return interval is thus ineffectual since contact 204 is open.

While the projector 31 is scanning the white area between the margin feed markatransmitting relay I14 will be ole-energized as already indicated and relay I92 will operate and pull up its contact tongue I94. This now provides a locking circuit for line feed magnet I36 which extends through contact tongue I94 of relay I92, contact tongue 2 I9 of relay 2I4, and over lead I81 to lead I86, which completes the circuit to magnet I36 as before. Now even though contact I88 is opened by cam I42 to break the original circuit for line derstood that the line feeding operation completed before shaft2'4 completes 'a'singlerevolution. It'is possible to have multiple line feeding operations as long as'the line feeding operations are completed with shaft 24 angular position.

in a predetermined I It should be further observed, that when the new feed mark is scanned contact tongue 20I of relay I92 opens the locking circuit for relay I84 since at this time relay I14 energizes and relay I92 de-energizes. A circuit may now be traced from battery, through clutch magnet 82, through contact pair I8I, over lead I82, through tongue I83 (now on its back contact) of relay I84, over leads I86 and I81, through contact tongue I88 of cam I42 and over lead 252 to grounded contact tongue 253 of slow-to-operate relay 22I. Clutch magnet 82 is therefore energized and projector 31 now starts its travel to scan the new line of code marks and after it moves a slight distance off the margin feed mark roller 81 (Fig. 4) it returns contact tongue 238 to its original position where it provides a charging path for condenser 239 for its next operation. Since contact tongue I89 of polar relay I9I is still remaining on its right-hand contact, a locking circuit will still be made over lead 2I3 for relay 2I4. Thus the projector 31 continues to advance to the feed mark accompanying the first code mark combination of the new line. However, when contact I99 is now operated by cam I43 with contact 204 closed by cam 206, contact tongue I89 of polar relay I9I will move against its left-hand contact, as the left-hand winding of polar relay I9I receives a pulse because contact tongue 20I of relay I92 is on its back contact since transmitting relay I14 is at this time energized. Thus relay 2I4 and slow-to-operate relay 22I will be unoperated and the circuit will be returned to normal scanning condition. It will be understood that contact I99 will be operated just after the feed mark is reached, assuming, of course, a normal spacing condition. Clutch magnet 82 is now halted in its code mark scanning position since a circuit is no longer completed through contact tongue 253 of relay 22 I. Further, since it is assumed that normal spacing exists between characters, relay I92 is de-energized and the abnormal spacing circuit described earlier in the specification as extending through contact tongue I94 of relay I92 and tongue 2I9 of relay 2I4 over lead I81 to lead I83, cannot be completed.

A rsum of the operation will now be given. When normal spacing exists between feed marks, after the transmission of a set of code marks has been made, clutch magnet 82 is energized and the projector 31 moves towards the next feed mark and its accompanying set of code marks with the shutter 59 in feed mark scanning position. When the next feed mark is reached, the projector 31 halts to scan it accompanying code marks with the shutter 59 in its code mark scanning position. If abnormal spacing occurs, relay 2I4 operates, the stop impulse to the line is prolonged and the shutter 59 is held in its feed mark scanning position, while the projector 31 continues to move toward the next feed mark and its accompanying code marks. When the next feed mark is reached the projector is halted and the code mark combination is transmitted after contact tongue I99 closes to operate the lefthand winding of polar relay I9I and thus release relay 2I4. When the end of the line is reached, prolonged scanning of an unmarked or white area causes relay 2I4 to operate slow-to-operate relay 22I. Operation of relay 22I provides a circuit for energization of carriage return clutch magnet 93 which returns projector 31 to its beginning of line position. Double wound relay I84 is now operated and a circuit is completed for the line feed magnet I36 which energizes and thereby enables a new line of the page form to be scanned. The projector 31 now proceeds from the mar gin feed mark of the new line of code marks to the feed mark accompanying the first set of code marks to be transmitted. At this time, contact 264 operable by cam 296 of carriage return sleeve 96 will have been closed and the left-hand winding of polar relay I9I is pulsed, opening the circuit for relay 2 I 4 and returning the transmitter to normal scanning condition.

With particular reference to Figs. 7, 9, 11 and 13, which correspond to similar figures of the six unit transmitter, and to Fig. 15, a description will now be given of a five unit code transmitter which automatically inserts shift signals. It will be understood that the same transmitting apparatus, with minor changes, will be used in this case as was used in connection with the six unit transmitter.

When the five unit transmitter is to be used, I;

a scanning disc 254 (Fig. '7) is provided on shaft 24 in place of disc 3| (Fig. 6). It will be noted that disc 254 includes a smaller transparent arouate area 256-8 which represents the shift on sixth code element of a code combination and g,

cupies approximately one half of the start impulse area. There is no transparent area for the start or stop impulses, since such impulses are transmitted by cam operated contacts to be later identified. It will be further noted (Fig. 7) that :l'

59, in that an additional aperture 258 and a pro- :2:

jection 269 are provided for control of the shift or sixth code element of the code marks.

remembered that the projector is now scanning a white area between feed marks and that relay I14 is de-energized while relay I92 is energized. When the next feed mark is reached relay I92 will de-energize and its contact tongue will fall away to break the circuit for clutch magnet 82, thereby stopping the projector. Contact tongue 26I of cam 262 will now be opened and the circuit to shutter magnet 62 will be broken to permit scanning of the new set of code marks. I

In each cycle of operation, a marking or stop impulse is transmitted as follows: From battery, over leads 216, 211, through tongue 213 of cam I4I, over lead 219, through make-before-break contacts 28I of double wound relay 266, through make-before-break contacts 282 of double Wound relay 268, through make-before-break contacts 283 of relay 284, and over lead 286 to line I16 extending to the distant station I11. During the start impulse period contact 218 of cam I4I opens insuring that the circuit just described will be opened. Furthermore, during the start interval,

I contact 231 of cam 288 will open, so that inde- Reference should now be had to Fig. of the drawings for the circuit arrangement of the five unit transmitter. Where parts are substantially the same as parts appearing in Fig. 14, similar numerals will be used and the description will be repeated only where necessary for a full understanding of the invention. Leads I18, 224, I82, and 251 represent similarly numbered leads extending approximately from the middle portion of the circuit appearing in Fig. 14 on the line A-A. Transmitting relay I14 is operated as before according to the scanning of the printed feed and code marks.

It will now be assumed that the five unit transmitter is in operation and that normally spaced characters in a line are being scanned. It will be further assumed that shaft 24 is in the position shown in Fig. 15. In this position a circuit for the shutter magnet 62 now extends from ground, through contact 26I of cam 262 and over lead I18 to the shutter magnet 62. At this time, therefore, shutter 251 is in its feed mark scanning po-- sition. Projector magnet 82 is energized at this time, causing the projector 31 to advance towards the next feed mark over the following circuit: From lead I 82 which extends to projector magnet 82, through contact I83, now on its back contact, over lead 263, through contact tongue 264 of relay 266, through contact tongue 261 of relay 268, over lead 269, through contact I88 when closed by cam I42, over leads 21 I, 212 to grounded contact tongue I89 of polar relay I9I now on its left contact. After contact I88 oi cam I42 is opened the circuit for magnet 82 now extends as follows: relay I84 as before, over leads 213, 214, through contact tongue I91, and over lead I96 to contact tongue I94 of relay I92 to ground. It should be From lead I82, through tongue I83 of pendently of the condition of relay I14, the start impulse will be transmitted except when abnormal spacing occurs or during end of line operations as will hereafter appear. After the sending of the start impulse scanning disc 254 scans the five code marks and accordingly relay I14 is operated and signals are sent over the line I16. Automatic insertion of shift signals will be explained later.

At some point near the end of the stop impulse period, cam 543 will close contact I99 and send a pulse through either the left-hand or righthand winding of polar relay I9I as described earlier in the specification in connection with the six unit code transmitter. If for some reason abnormal spacing between characters occurs, the

L right-hand winding of polar relay I9I receives a pulse through contact I99 and tongue I89 of relay I9! moves to its rightward position to close an obvious circuit extending overlead I81 to relay 2| 4. When relay 2I4 operates steady marking current is placed on the line by a circuit extending from lead ZIB, over tongue 2I6 (now closed) of relay 2I4 and over lead 289 to lead 219 which extends to line I16 as previously de scribed. Furthermore, at this time contact tongue 2I8 of relay 2M will be drawn up completing a circuit over lead I18 for shutter magnet 62 which holds shutter 251 in its feed mark scanning position. The projector continues to advance to the next feed mark as magnet 82 is energized over a circuit extending from contact tongue I94 of relay I92 (now energized since a white area is being scanned) over lead I96, through tongue 2I9 (now closed) of relay 2I4, over leads 214, 213, and through tongue I83 of relay I84 to lead I82 as before. As soon as a black feed mark is scanned, relay I14 will energize and relay I92 will de-energize and tongue I94 of the latter relay will break the circuit just described and stop the projector 31. Now when contact I99 of cam I43 closes, the left winding of polar relay I9I will be pulsed and the circuit of relay 2I4 will be broken. The line will now be freed for code mark scanning purposes and the shutter will move to its code mark scanning position. It will be noted that while the next feed mark is reached in the previous cycle that during this period the line is kept closed and the signal which had been delayed by abnormal spacing is now transmitted. l

It will now be assumed that there is a'pro' asst-m longedfscanning of a white area at the end or a line as was pr'eviouslydescribed connection with the six unit code transmission, Relays I92 and 2I4 are energized at this time and when 'make before-break contact 29I is operatedmo- 'mentarily by cam 292, a circuit may now .be

trac d from contact tongue 293 of relay I92, through contact tongue 294 of relay 2I4, over lead 296, through contact 291, the operation of which will be explained later, over lead 298, and

contact tongue 30I is operated by relay 284, a

circuit may be traced over lead 224 to carriage return magnet 93 and the projector is returned to its beginning of line position as described previously; When make-before-break contact tongue '283is operated .by relay 284, a carriage return transmitting contact 302 operable by a suitably notched earn 303 is placed in circuit with line I16 in a circuit extending from battery 304, through contact 302 (when closed) over lead 306, through make-before-break contact 283 now held inits operated position by relay 284 to lead 286 which exten ds to line I16 Thus, at this time a carriage return signal is automatically sent to distant station I11 during the first revolution of shaft 31 when the projector returns to its beginning of line position.

.When the projector 31 reaches itsbeginning of line position, contact bank 301 is operatedby a roller 81, carried by rack 84 (Fig. 4) of the transinitting apparatus, thereby moving contact bank 301 to the left. As contact 238 is moved to the left, condenser 239 discharges through the left winding of double wound relay I8 4 over lead 24 I, when the high portion of Cain l42closes Contact 242. An-

other circuit may be established for the looking or right-hand winding of relay I84, when the margin reed mark of the line or codemarks, just transmitted is" scanned since the projector has returned ,to" its beginning of line positionas follows: From battery, through the right-hand f During the line feed operation a white are will be scanned between the margin .ie'ed' mark of the line' just scanned andithe margin feed mark of the next line to be s'cannedas .tl'l'e page form is fed upwardly. The locking circuit for relay I84" will now be made as" follows: From battery, through the right-hand winding of relay I 84, through its contact tongue 243, over leads 244, 3I I, and through contact tongue 246 when closed by cam I42 to ground. When the white I area mentioned above was scanned,'anew circuit for line feed magnet I36 is establishedflw'hich extends over lead-25 I',through"contac't tongue I 83 as" before, over leads 213', 214', through tongue 2I'9 of relay 2I4' and over lead I96 to' grounded contacttongue I94'of relay I92. 7

When the. new margin feed mark' is reached; relay I92 is released causing relay I84 toldeenergize and the circuit for. the line feeding oper. ation just described. is broken 'an'dIthe; feeding of the page form ceasesl The projector 31" is now ready to scan the new line oif code marks. With the relay I84 de energiZed and relay I 94 released, a circuit for the magnet 82 is now established when contact I88 of cam I42 is closed as follows: From lead I82, through tongue I83 (now on its back contact) through contact I 88, when closed by cam I42, over leads 21I, 212 to grounded contact tongue 309 of bank 301. With magnet 82 energized the projector 31 now movestowards the next feed mark. After it movesa slight distance onto the white area between adjacent feed marks of the new line, contact bank 301 will be opened as roller 81 (Fig. 4) moves away and contact tongue 309- will open the just described circuit for magnet 82. However, even though opening of tongue 309 breaks thecircuit for rnagn et 82 as described above, a circuit at this time may be traced through contact tongue I83, over leads 213, 214, through contact tongue 2 I9 of slow-toope rate relay 2l4, still operated since tongue I89 of polar relay I9I is against its right contact, and over lead I96 to grounded contacttongue 293 of relay 692 now energized since a white area is being scanned. Thus, the projector 31 continues to move to the feed markacconipanying.the first code mark combination of the new line. However, when contact I99 is now operated by cam I43 with contact 204 closed by cam 206, contact I89 of polar relay I9I will move against its lefthand contact as the left-hand winding of relay I9I receives a pulse completed because contact tongue 20I of relay I92 is on its back contact since transmitting relay I14 is at this time energized due to the scanning of the next feed mark This stops advancement of the projector 31 and the first code mark combination of the new line is transmitted. I v

An explanation will now be given of the transmission of a figures shift signal. It will be assumed that the letters shift signal was at some time previously transmitted as willlater be described. During the first half of the start in;- pulse period, scanning disc254 (Fig. 7) by means of transparent area 256-5 scans the sixth code mark or shift area and senses a black code mark which is indicative of a figures shift condition. At this time, of course, shutter 251 (Fig. 13) places aperture 258 in its scanning position. It should be mentioned that the high portion of cam 262 retains contact ZBI closed duringthe stop impulse period and for one-half of the start impulse period and thus during this time shutter 251 is in its feed mark or sixth code mark scanning position. During the first half of the start impulse, cam 3I2 closes contacts 313, 3I 4, and since at this time the sixth code mark is being scanned, a circuit may be traced as follows: From battery, through contact tongue 3I6 of relay 2I4, over lead 3I1, through the left-hand windingof polar relay 318, through closed contact 3I3, and over lead 3I9 to groundedcontact tongue 20 I of relay I92. Contact tongue 320 of polar relay 3I8 previous to this has been resting on its righthand contact tongue, and condenser 32! has been receiving a charge from battery, through the lefthand winding of relay 268, over lead 322. Contacttongue 320 now moves against its left-hand contact and condenser 32I discharges through the left-hand winding of relay 200.

Relay 266 now operates and locks up throughits right-hand winding, through contact tongue 323, over leads 322 and 324, and through closedpath now extends as follows: From battery 304,

througlitransmitting cOntaCt 32s of figures shift cam 329, through make-before-break contact 28! of relay 266, now operated, through make-beforebreak contact 282 of relay, 268, through makebefore-break contact 283 of relay 284 and over lead 286 to signal line I16. It will be noted that at this time, the transmitting circuit for relay I14 which extended over lead 219 is at this time broken clue to the operation of make-beforebreak contact 253i of relay 266 so that relay I74 cannot send signals to the line. Cam 329 now operates contact 328 and causes transmission of a figures shift signal. i

During the start interval, contact 33! is opened by cam 288 and contact 328 is opened by cam 329, so that the energization of relay 266 during the start interval has no effect on start impulse transmission. Relay 266 remains operated for the entire cycle while the figures shift signal is being transmitted until cam 32'! opens contact 325. During this'time contact tongue 264 of relay 266 is in its attracted position and prevents travel of the projector by blocking completion of the initially described circuit for magnet 82. Just after contact 588 is closed by cam I52 and prior to the time earn 352 operates contacts 3l3, 3M, cam 32! will operate contact 326 and break the locking circuit for relay 266 which now releases. Relay H4 now gains control of the line as make-beforebreak contact 28! of relay 26$ moves to its unattracted position and enables transmission of the first code signals accompanying the sixth code mark which caused transmission of the figures shift signal.

When the sixth code mark is not printed, indicating a change from a figures to a letters condition, the sixth code area is scanned, and since this area is not printed relay il will be unoperated and relay 92 will be operated. The result of this is that when cam 3P2 closes contacts 3E3, 3, a circuit is now made from grounded contact tongue 2M of relay I92, over lead 308, through contact 314, through the right-hand winding of polar relay 3 i 8, over lead 3 i i, and through contact tongue 316 to battery. This causes contact tongue 326 of polar relay 3H8 to move against its right-hand contact and charge condenser 32! through the left-hand winding of relay 268, over lead 322. As relay Z63 operates, a signaling circuit is now established as follows: From battery 364, through.

transmitting contact 33i controlled by cam 288, through make-before-break contact 282 now at-' tracted by relay 268, through make-before-break contact 283 of relay 23d, and over lead 286 to line H6. Cam 288 now functions to send the all marking or letters shift signal to line :76 by operation of contact 33!. When relay 268 operated, it locked up through its right-hand winding through contact tongue 332 and through contact 326 controlled by cam 327. Contact tongue 264 is now held attracted by relay266 preventing the release of the projector by operation of projector magnet 62 over its initially described operating circuit. Cam 327 releases relay 268 by opening contact 326 as was described above in con-, nection with relay 26$. After the letters shift signal is transmitted, the code marks accompanying the first appearance of the letters shift characters is now transmitted. In order to prevent polar relay 3I8 from being operated during abnormal spacing or when the end of line is scanned, contact tongue 3H5 of relay 2| 4 is attracted under such conditions. Contact 291 of contact bank 36'! is opened when the projector 37 reaches its beginningof line position to prevent operation of relay 284 under such conditions 18 so that a second carriage return signal will not be transmitted.

Continuous iced out of a page form is accomplished when the last line of a page is scanned by providing a black margin feed mark under plate 53 where plate 54 is slotted at 56. This margin feed mark would be in direct line with the margin feed marks of the page form. Thus, after the last line is scanned and the projector is returned to the beginnin of line position, the line feed mechanism will continuously feed out the page form until the painted margin feed mark is scanned. A suitable alarm device could be provided to indicate that the end of the page form has been reached.

Various changes and modifications may be made in the herein described invention Without departing from the spirit or scope thereof.

What is claimed is:

1. In a photoelectric transmitting apparatus, a page form supporting means adapted to receive a page form having transverse lines of code mark combinations thereon, an optical system including a pivoted projector for scanning said code marks, means for intermittently advancing said projector to scan sequentially the individual code mark combinations of a line of said code mark combinations, light sensitve means operable in accordance with the sequential scanning of said code marks by said optical system, and transmitting mcans associated with said light sensitive means for transmitting signals in accordance with the operation of said light sensitive means.

2. In a photoelectric transmitting apparatus, a page form supporting means adapted to receive a page form having transverse lines of code mark combinations thereon, an optical system for scanning said code marks including a pivoted projector, means for automatically varying the focal length of said projector in accordance with the area of the page form being scanned, means for intermittently advancing said projector to scan sequentially the individual code mark combinations of a line of said code mark combinations,

light sensitive means operable in accordancewith the sequential scanning of said code marks by said optical system, and transmitting means associated with said light sensitive means for transmitting signals in accordance with the operation of said light sensitive means.

3. In a photoelectric transmitting apparatus, a page form supporting means adapted to receive' a page form having transverse lines of code mark combinations thereon, an optical system including a pivoted projector for scanning said code marks, means for intermittently advancing said projector to scan sequentially the individual code mark combinations of a line of said code mark combinations, light sensitive means operable in accordance withthe sequential scanning of said code marks by said optical system, transmitting means associated with said light sensitive means for transmitting signals in accordance with the operation of said light sensitive means, means for automatically returning said projector to its beginning of line position after a line of code marks have been scanned, and means for feeding said page form to bring anew line of code marks into scanning position.

4. In a photoelectric transmitting apparatus, page form supporting means adapted to receive a page form having transverse lines of code mark combinations thereon, an optical system for scanning said'code marks including a pivoted projector, a rack for driving said pivoted projector,

mam

V 19 means for intermittently operating said rack to drive said projector and thus enable said projector to scan sequentially the. individual code mark combinations, light sensitive means operable in accordance with the sequential scanning of said code marks by said optical system, and transmitting means associated with said light sensitive means for transmitting signals in accordance with the operation of said light sensitive means. 5. In a photoelectric transmitting apparatus, page form supportingmeansadapted to receive a page form having transverse lines of code mark combinations thereon, an optical system for scanning said code marks including a pivoted projector, a rack for driving said pivoted projector, means for intermittently,operating said rack to drive said projector in one j'direction for scanning sequentially individual code mark combinations, light sensitive means operable'inaccordance with the sequential scanning oi aid'code marks by said optical system, transmitting means associated with said light sensitive nieansfor transmitting signals in accordanew'ith the operation of said light sensitive means, and means operative when said projector has'reached an end'of line position for operating said'rack to' thereby drive said projector inthe' opposite'directio'n to its beginning of line position. X

6. In a photoelectric transmitting apparatus,

page form supporting means adapted to receive means for intermittently operating said'r'ack to drive said projector in one direction for scanning sequentially individual code markcombinations, light sensitive means operable in accordance with the sequentials'ca'nni'ng of said code marks by said optical system, transmitting means associated with said light sensitive means for transmitting signals inaccor'dance withthe open ation of said light sensitive means, means responsive when said projector has "reacneaanend' of line position for operating'said rack wther'ety drive said projector in the opposite direction to its beginning of line position, and linefeedmeans operative when said projector has'reached its beginning of line'po'sition for advancing a page'form to bring a new line of code marks into scanning position.

'7. In a photoelectric transmitting apparatus, a page form supporting means adapted to receive a page form having transverse line'sof code mark combinations thereon, an optical systemincluding a pivoted projector for scanning said code" marks, means including a clutch for intermittently advancing said projector to scan sequentially the individual code mark combinations" of a line of said code mark combinations, light sensitive means operable in accordance with th s quential scanning of said code marks by" said'o'ptical system, and transmitting means associated individual code mark combinations, light'sen's'i tive means operable in accordance with the sequential scanning of said code marks by'said opti cal system, and transmitting means associated with said light sensitive means for transmitting signals in accordance with the operation of'said light sensitive means,

9. In a photoelectric transmitting apparatus, page form supporting'mean's adapted to receive a page form having transverse lines of code mark combinations thereon, 'anoptical system for scanning said code marks including a pivoted projector, a rack for driving said pivoted projector, means including a clutch fo'r intermittently operating said rack to drive said projector, in one direction for scanning sequentially individual code mark combinations, light sensitive means operable in accordance with the sequential scanning of said code 'marks by said optical system, transmitting means associated with said light sensitive means for transmitting signals in accordance with the operation of said light sensitive means, and means including a clutch operative when said projector has reached an end'of line position for operating said rack to thereby drive said projector in the opposite direction to its beginning of line position.

10. In a photoelectric transmitter, control form supporting means for supporting a control form having indicia thereon, a light sensitive device, a movable projector including arlens system for projecting sequentially images of said indicia from different areas of a control form to said light sensitive device to thereby operate said light sensitive device, means for automatically varying the focal length of said lens system in accordance with the distance through which an image is projected from a particular area of said control form to said light sensitive device, and transmitting means associated with said light sensitive device to transmit signals in accordance with the operation of said light sensitive device.

11. In a photoelectric transmitter, page form supporting means adapted to receive a page form having transverse lines of code mark combinations thereon, an optical system including a movable projector for scanning said code mark combinations, a rack on which said projector is moved, means for moving'said projector on said rack step by step from one code combination to another to scan sequentially the individual code combinations, a light sensitive device operable by said optical system, and transmitting means operable under the control of said light sensitive device for transmitting signals representative of the code marks scanned by said optical system.

12. In a photoelectric transmitter, page form supporting means adapted to receive a page form having transverse lines of code mark combinations and an individual feed mark'for'eachcode mark combination thereon, and optical system including a pivoted projector for scanning said code mark combinations and said feed marks, means for advancing said projector step by step from one code mark combination to another to scan the individual code mark combination, a light sensitive device operable by said optical system, said, projector being stopped in its step by step advancement at each code combination in response to the scanning of a feed mark by said optical system, and transmitting means operable under the control of said light sensitive device for transmiting signals representative of the code marks scanned by said optical system.

13. In a ph'otoele'ctric transmitter, page form supporting means adapted to receive a page form having transverse lines of code mark combinations, an individual feed mark for each code combination and a margin feed mark for each line of code marks, an optical system including a movable projector for scanning said code marks and said feed marks, means for advancing said projector step by step from one code mark combination to another, means for enabling the sequential scanning of the individual codemarks of the combinations by said optical system, light sensitive means operable by said optical system in response to the scanning of said code marks and said feed marks, said projector being stopped in its step by step advancement at each code combination in response to the scanning of a feed mark by said optical system, transmitting means operable under the control of said light sensitive device for transmitting signals representative of the code marks scanned by said optical system, means for automatically returning said projector to its beginning of line position after a line of code marks have been scanned, line feed means operative when said projector has reached its beginning of line position for advancing said page form, and means for disabling said line feed means when the margin feed mark of the next line of code marks is scanned by said optical system.

14. In a photoelectric transmitting apparatus, a page form supporting means adapted to receive a page form having transverse lines of code mark combinations thereon including a shift control mark, an optical system including a movable projector for scanning said code marks and shift control mark, means for advancing said projector across said page form to scan sequentially the individual code mark combinations,'light sensitive means operable in accordance with the sequential scanning of said code marks by said optical system, transmitting means associated with said light sensitive means for transmitting signals in accordance with the operation of said light sensitive means, means responsive to the scanning of the presence of said shift mark for automatically transmitting one type of shift signal, and means responsive to the scanning of the absence of said shift mark for automatically transmitting another type of shift signal.

15. In a photoelectric transmitting apparatus, page form supporting means adapted to receive a page form having transverse lines of six unit code mark combinations, an optical system for sequentially scanning the individual marks of each code combination including a movable projector, means for advancing said projector step by step from one code mark combination to another, light sensitive means operable in accordance with the sequential scanning of said code mark combinations by said optical system, transmitting means associated with said light sensitive means for transmitting five unit code signals in accordance with the operation of said light sensitive means, means operable in response to the scanning of a sixth code mark by said optical system for automatically transmitting one type of shift signal, and means operable in response to the failure of said optical systems to scan a sixth mark for automatically transmitting another type of shift signal.

16. In a photoelectric transmitter, page form supporting means adapted to receive a page form having transverse lines of code mark combinations, an optical system including a movable projector for scanning said code mark combinations,

step from one code combination to another to scan sequentially the individual code combinations, light sensitive means operable by said optical system, transmitting means operable under the control of said light sensitive means for transmitting signals representative of the code marks scanned sequentially by said optical system, and means for automatically transmitting an end of line signal when said optical system has completed the transmission of a line of code mark combinations.

17. In a photoelectric transmitter, page form supporting means adapted to receive a page form having transverse lines of code mark combinations thereon, an optical system includin a movable projector for scanning code mark combinations, means for moving said projector step by step from one code combination to another to scan sequentially the individual code combinations, light sensitive means operable by said optical system, transmitting means operable under the control of said light sensitive means for transmitting signals representative of the code mark combinations scanned sequentially by said optical system, and means for automatically providing a start and stop signal to accompany each group of code mark combination signals transmitted.

18. In a photoelectric transmitting apparatus, page form supporting means adapted to receive a page form having transverse lines of code mark combinations and a feed mark individual to each code combination recorded thereon, an optical system for scanning said code and feed marks including a movable projector, means for moving said projector step by step from one code combination to another to scan sequentially the individual code mark combinations, light sensitive means operable by said optical system, the travel of said projector being halted in each step by step movement by the scanning of a feed mark, transmitting means operable under the control of said light sensitive means for transmitting signals representative of the code mark combinations scanned sequentially by said optical system, means for automatically providing a start and stop signal to accompany each group of code mark combination signals transmitted, and means for prolonging said stop impulse beyond the normal duration while said projector is traveling from one feed mark to another until the new feed mark is scanned.

19. In a photoelectric transmitting apparatus, page form supporting means adapted to receive a page form having transverse lines of code marks and spaced feed marks individual to each code mark combination thereon, an optical system including a movable projector, means for moving said projector step by step from one code combination to another to scan sequentially the individual code mark combinations, light sensitive means operable in accordance with the sequential scannin of said code and feed marks by said optical system, transmitting means associated with said light sensitive means for transmitting signals in accordance with the operation of said light sensitive means, means operable in response to the scanning of a feed mark for halting said projector in its step by step movement at its accompanying code mark combination to scan said code mark combination, and means responsive to the scanning of a blank area beyond a fixed limit of time by said optical system at the end of a line REFERENCES CITED 7 The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 605,222 Deses'et a1. Nov. 2, 1926 2,036,128 Finch Mar. 31, 1936 2;183,559 Green Dec. 19, 1939 2;-274;-737 Potts -Mar, 3, 1942 

